Heat exchange unit

ABSTRACT

A heat exchange unit performs at least one of a cooling and a heating of a liquid medium that is sent to a utilization side equipment. The heat exchanging unit includes: a heat exchanger that exchanges heat between a flammable refrigerant and the liquid medium; a casing that accommodates the heat exchanger; a drain pan with a bottom plate and a side wall that extends upward from the bottom plate; and a first gas detection sensor that detects presence or absence of a gas of the refrigerant in an internal space of the drain pan. The internal space is a space within the drain pan that is surrounded by the bottom plate, the side wall, and a virtual plane passing through an upper end part of the side wall. The drain pan is disposed below the heat exchanger in a lower part of the casing.

TECHNICAL FIELD

The present disclosure relates to a heat exchange unit that exchanges heat between a refrigerant and a liquid medium sent to utilization-side equipment, to cool or heat the liquid medium.

BACKGROUND

Conventionally, there is known a heat exchange unit that exchanges heat between a refrigerant and a liquid medium sent to utilization-side equipment, to cool or heat the liquid medium. For example, Patent Literature 1 (WO 2014/97440 A) discloses a heat exchange unit that cools brine or the like with a refrigerant in a heat exchanger arranged in a relay device, and sends the cooled brine or the like to utilization-side equipment.

PATENT LITERATURE

-   Patent Literature 1: WO 2014/97440 A

Meanwhile, in this heat exchange unit, a flammable (including mildly flammable) refrigerant may be used in consideration of various characteristics of the refrigerant. However, when a flammable refrigerant is used in the heat exchange unit, there is a possibility of ignition if the refrigerant leaks for some reason.

Therefore, in the heat exchange unit that uses a flammable refrigerant, highly reliable refrigerant leakage detection is desired.

SUMMARY

A heat exchange unit according to one or more embodiments exchanges heat between a liquid medium sent to utilization-side equipment and a refrigerant that is flammable, to perform at least one of cooling and heating of the liquid medium. The heat exchange unit includes a heat exchanger, a casing, a drain pan, and a first gas detection sensor. The heat exchanger exchanges heat between the refrigerant and the liquid medium. The casing accommodates the heat exchanger. The drain pan is arranged below the heat exchanger, in a lower part of the casing. The drain pan has a bottom plate and a side wall extending upward from the bottom plate. The first gas detection sensor detects the presence or absence of refrigerant gas in an internal space of the drain pan, the internal space being located above the bottom plate of the drain pan and below an upper end part of the side wall of the drain pan.

The refrigerant gas is usually heavier than air. Therefore, when the refrigerant leaks, the leaked refrigerant gas moves downward. Therefore, in this heat exchange unit, leaked refrigerant gas tends to accumulate in the drain pan that is arranged in the lower part of the casing and receives dew condensation water generated on a pipe, the heat exchanger, and the like.

Here, highly reliable refrigerant leakage detection is possible by detecting the presence or absence of refrigerant gas in the internal space of the drain pan where leaked refrigerant gas tends to accumulate.

In one or more embodiments, the first gas detection sensor has a first detection element arranged in the internal space of the drain pan, and detects the presence or absence of refrigerant gas at a place where the first detection element is arranged.

Here, by arranging the detection element of the first gas detection sensor in the internal space of the drain pan where leaked refrigerant gas tends to accumulate, highly reliable refrigerant leakage detection is possible.

In one or more embodiments, the bottom plate of the drain pan has an inclined part that is inclined with respect to a horizontal plane. The first detection element is arranged on a lower end side of the inclined part.

Here, since the detection element of the first gas detection sensor is arranged on the lower end side of the inclined part where the refrigerant gas tends to accumulate, highly reliable refrigerant leakage detection is possible.

In one or more embodiments, at least one of the bottom plate and the side wall of the drain pan is provided with a drain port for discharge of water in the internal space of the drain pan. The first detection element is provided near the drain port.

Here, since the detection element of the first gas detection sensor is arranged near the drain port of the drain pan that is arranged at a position where water is easily discharged, highly reliable refrigerant leakage detection is possible.

In one or more embodiments, a heat exchange unit further includes a float arranged in the internal space of the drain pan. The first detection element is attached to an upper surface or a side surface of the float.

Here, since the detection element of the first gas detection sensor is attached to the upper surface or the side surface of the float, it is possible to detect refrigerant leakage even when water accumulates in the drain pan.

In one or more embodiments, a heat exchange unit further includes a second gas detection sensor. The second gas detection sensor has a second detection element arranged outside the casing. The second gas detection sensor detects the presence or absence of refrigerant gas at a place where the second detection element is arranged.

Here, even if the refrigerant gas flows out of the casing, refrigerant gas can be detected by the second gas detection sensor provided separately, which enhances safety.

In one or more embodiments, the casing is formed with an opening for maintenance. The first detection element is arranged in a space near the opening.

Here, since the detection element of the first gas detection sensor is arranged in the space near the opening for maintenance, the detection element of the first gas detection sensor can be easily inspected and replaced.

In one or more embodiments, a heat exchange unit further includes a pump. The pump is arranged inside the casing. The pump sends the liquid medium to the utilization-side equipment. An inside of the casing is sectioned into at least a pump arrangement area and a refrigerant side area in plan view. In the pump arrangement area, the pump is arranged. In the refrigerant side area, a refrigerant pipe through which the refrigerant flows or the heat exchanger is arranged. The first detection element is arranged closer to the refrigerant side area than the pump arrangement area in plan view.

Here, since the detection element of the first gas detection sensor is arranged, inside the casing, relatively close to the heat exchanger or the refrigerant pipe through which the refrigerant flows, highly reliable refrigerant leakage detection is possible.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a heat exchange unit according to one or more embodiments.

FIG. 2 is a schematic configuration diagram of a heat load processing system including the heat exchange unit of FIG. 1.

FIG. 3 is a schematic plan view of a machine room that is an installation place of the heat exchange unit of FIG. 1.

FIG. 4 is a schematic front view of the heat exchange unit of FIG. 1.

FIG. 5 is a schematic plan view of a lower part inside a casing of the heat exchange unit of FIG. 1.

FIG. 6 is a schematic front view of the heat exchange unit of FIG. 1 with a side plate of the casing removed.

FIG. 7 is a schematic right side view of the heat exchange unit of FIG. 1 with a side plate of the casing removed.

FIG. 8 is a schematic plan view of a drain pan of the heat exchange unit of FIG. 1.

FIG. 9 is a schematic rear view of a part of the casing of the heat exchange unit of FIG. 1 and the drain pan of FIG. 8.

FIG. 10 is a schematic right side view of the drain pan of FIG. 8.

FIG. 11A is view obtained by schematically drawing an example of a float installed in an internal space of the drain pan of FIG. 8.

FIG. 11B is view obtained by schematically drawing another example of the float installed in the internal space of the drain pan of FIG. 8.

FIG. 12 is a schematic front view of a heat exchange unit of Modified example 1B.

FIG. 13 is a perspective view of a heat exchange unit according to one or more embodiments.

FIG. 14 is a schematic configuration diagram of a heat load processing system including the heat exchange unit of FIG. 13.

FIG. 15 is a schematic plan view of a lower part inside a casing of the heat exchange unit of FIG. 13.

FIG. 16 is a schematic front view of the heat exchange unit of FIG. 13 with a side plate of the casing removed.

FIG. 17 is a schematic right side view of the heat exchange unit of FIG. 13 with a side plate of the casing removed.

FIG. 18 is a schematic rear view of a part of the casing of the heat exchange unit of FIG. 12 and a drain pan of the heat exchange unit of FIG. 12.

FIG. 19 is a specific example of a refrigerant used in the heat exchange units of one or more embodiments.

DETAILED DESCRIPTION

Hereinafter, embodiments of a heat exchange unit will be described.

First Embodiment (1) Overall Configuration

A heat exchange unit 100 according to one or more embodiments and a heat load processing system 1 including the heat exchange unit 100 will be described with reference to the drawings.

FIG. 1 is a perspective view of the heat exchange unit 100. FIG. 2 is a schematic configuration diagram of the heat load processing system 1 including the heat exchange unit 100. Note that, in FIG. 2, an internal configuration is drawn only for one of four heat source units 300, and drawing of an internal configuration of the other three is omitted. FIG. 3 is a schematic plan view of a machine room R where the heat exchange unit 100 is installed. FIG. 4 is a schematic front view of the heat exchange unit 100. FIG. 5 is a schematic plan view of a lower part inside a casing 90 of the heat exchange unit 100. FIG. 6 is a schematic front view of the heat exchange unit 100 with a side plate of the casing 90 removed. FIG. 7 is a schematic right side view of the heat exchange unit 100 with a side plate of the casing 90 removed.

Note that, in the following description, expressions indicating directions such as “upper”, “lower”, “left”, “right”, “front (front face)”, and “rear (back face)” may be used. Unless otherwise specified, these directions are indicated by arrows in figures.

The heat load processing system 1 mainly includes the heat exchange unit 100, the heat source unit 300, and utilization-side equipment 410.

The heat exchange unit 100 is a unit that exchanges heat between a liquid medium and a refrigerant, to perform at least one of cooling and heating of the liquid medium. In particular, the heat exchange unit 100 of one or more embodiments performs both cooling and heating of the liquid medium by exchanging heat between the liquid medium and the refrigerant. The liquid medium cooled or heated by a liquid refrigerant in the heat exchange unit 100 is sent to the utilization-side equipment 410.

Note that the liquid medium used in one or more embodiments is, for example, a heat medium such as water or brine. The liquid medium used as brine is, for example, an aqueous solution of sodium chloride, an aqueous solution of calcium chloride, an aqueous solution of ethylene glycol, an aqueous solution of propylene glycol, or the like. However, the liquid medium is not limited to the types exemplified here, and may be appropriately selected. In one or more embodiments, brine is used as the liquid medium.

In one or more embodiments, the refrigerant is a flammable refrigerant. Note that, here, flammable refrigerants includes refrigerants that fall into Class 3 (higher flammability), Class 2 (flammable), and Subclass 2L (lower flammability) in the standard of ASHRAE 34 Designation and safety classification of refrigerant of the United States of America, or the standard of ISO 817 Refrigerants—Designation and safety classification. For example, FIG. 19 shows a specific example of the refrigerant used in one or more embodiments. “ASHRAE Number” in FIG. 19 indicates an ASHRAE number of a refrigerant defined by ISO 817, “Composition” indicates an ASHRAE number of a substance contained in the refrigerant, “Mass %” indicates a mass percent concentration of each substance contained in the refrigerant, and “Alternative” indicates a name of a substance of the refrigerant that is often replaced by the refrigerant. In one or more embodiments, the refrigerant to be used is R32. The refrigerants illustrated in FIG. 19 have a feature of having a higher density than air.

An installation place is not limited, but the heat exchange unit 100 is installed indoors, for example. In one or more embodiments, the heat exchange unit 100 is installed in the machine room R together with other devices (devices OD1 to OD3 in FIG. 3) as shown in FIG. 3. The devices OD1 to OD3 include, but are not limited to, a boiler, a generator, a switchboard, and the like. However, only the heat exchange unit 100 may be installed in the machine room R. Further, the heat exchange unit 100 may be installed outdoors such as on a rooftop of a building or around a building.

The heat source unit 300 is a device that uses air as a heat source to cool or heat the refrigerant. The heat source unit 300 is connected to the heat exchange unit 100 via a liquid-refrigerant connection pipe 52 and a gas-refrigerant connection pipe 54, and form a refrigerant circuit 50 together with the heat exchange unit 100. The refrigerant circuit 50 mainly has a compressor 330, a flow path switching mechanism 332, a heat-source-side heat exchanger 340, and a second expansion mechanism 344 of the heat source unit 300, which will be described later, a utilization-side heat exchanger 10 and a first expansion mechanism 20 of the heat exchange unit 100, which will be described later, and the like. An installation place is not limited, but the heat source unit 300 is installed, for example, on a rooftop or around of a building, or the like.

In one or more embodiments, the heat load processing system 1 has the four heat source units 300 (see FIG. 2). Then, the heat exchange unit 100 cools or heats the liquid medium with the refrigerant cooled or heated in the four heat source units 300. However, the number of heat source units 300 is an example, and the number is not limited to four. The number of heat source units 300 may be, for example, one to three, or five or more.

The utilization-side equipment 410 is equipment that uses or stores the liquid medium cooled or heated by the heat exchange unit 100. The utilization-side equipment 410 is connected to the heat exchange unit 100 via a liquid medium connection pipe 420 to form a liquid medium circuit 400. In the liquid medium circuit 400, the liquid medium sent by a pump 60 of the heat exchange unit 100, which will be described later, circulates.

The utilization-side equipment 410 is, for example, an air handling unit or a fan coil unit that performs air conditioning by exchanging heat between air and the liquid medium cooled or heated by the heat exchange unit 100. However, the utilization-side equipment 410 may be, for example, manufacturing equipment that cools or heats a manufacturing device or a manufactured product by using the liquid medium cooled or heated by the heat exchange unit 100. Further, the utilization-side equipment 410 may be, for example, a tank that stores the liquid medium cooled or heated by the heat exchange unit 100. The liquid medium stored in the tank as the utilization-side equipment 410 is, for example, sent to a device using the liquid medium by a pump or the like (not illustrated).

FIG. 2 illustrates only one piece of the utilization-side equipment 410. However, the heat load processing system 1 includes multiple pieces of utilization-side equipment, and the liquid medium cooled or heated by the heat exchange unit 100 may be sent to the multiple pieces of utilization-side equipment. When the heat load processing system 1 includes a multiple pieces of utilization-side equipment, types of the multiple pieces of utilization-side equipment may all be the same, or the multiple pieces of utilization-side equipment may include a plurality of types of equipment.

(2) Detailed Configuration

The heat source unit 300, the liquid-refrigerant connection pipe 52 and the gas-refrigerant connection pipe 54, the liquid medium circuit 400, and the heat exchange unit 100 will be described in detail.

(2-1) Heat-Source-Side Unit

The heat source unit 300 will be described with reference to FIG. 2. Note that, in FIG. 2, an internal configuration is drawn only for one of four heat source units 300, and drawing of an internal configuration of the other three is omitted. The heat source units 300 omitted from the drawing also have a configuration similar to the heat source unit 300 described below.

The heat source unit 300 mainly includes an in-unit refrigerant pipe 350, the compressor 330, the flow path switching mechanism 332, the heat-source-side heat exchanger 340, the second expansion mechanism 344, a fan 342, a gas-side shutoff valve 304, a liquid-side shutoff valve 302, and a heat-source-side control board 395 (see FIG. 2).

(2-1-1) In-Unit Pipe

The in-unit refrigerant pipe 350 is a pipe connecting between configurations of the heat source unit 300, including the compressor 330, the flow path switching mechanism 332, the heat-source-side heat exchanger 340, the second expansion mechanism 344, the gas-side shutoff valve 304, and the liquid-side shutoff valve 302. The in-unit refrigerant pipe 350 includes a suction pipe 351, a discharge pipe 352, a first gas-side pipe 353, a liquid-side pipe 354, and a second gas-side pipe 355 (see FIG. 2).

The suction pipe 351 is a pipe that connects a suction port (not illustrated) of the compressor 330 and the flow path switching mechanism 332. The suction pipe 351 is provided with an accumulator (not illustrated). The discharge pipe 352 is a pipe that connects a discharge port (not illustrated) of the compressor 330 and the flow path switching mechanism 332. The first gas-side pipe 353 is a pipe that connects the flow path switching mechanism 332 and a gas side of the heat-source-side heat exchanger 340. The liquid-side pipe 354 is a pipe that connects a liquid side of the heat-source-side heat exchanger 340 and the liquid-side shutoff valve 302. In the liquid-side pipe 354, the second expansion mechanism 344 is arranged. The second gas-side pipe 355 is a pipe that connects the flow path switching mechanism 332 and the gas-side shutoff valve 304.

(2-1-2) Compressor

The compressor 330 suctions a low-pressure refrigerant in a refrigeration cycle through the suction pipe 351, compresses the refrigerant by a compression mechanism (not illustrated), and discharges a high-pressure refrigerant in the refrigeration cycle after compression through the discharge pipe 352.

The compressor 330 is, for example, a scroll-type compressor. However, a type of the compressor 330 is not limited to the scroll type, and the compressor may be, for example, a screw type, a rotary type, or the like. The compressor 330 is, for example, a compressor having a variable capacity, but may be, for example, a compressor having a constant capacity.

(2-1-3) Flow Path Switching Mechanism

The flow path switching mechanism 332 is a mechanism to switch a flow direction of the refrigerant in the refrigerant circuit 50 in accordance with an operating mode of the heat load processing system 1. The operating modes of the heat load processing system 1 include a mode for cooling the liquid medium (hereinafter referred to as a cooling mode) and a mode for heating the liquid medium (hereinafter referred to as a heating mode).

In one or more embodiments, the flow path switching mechanism 332 is a four-way switching valve. However, the flow path switching mechanism 332 is not limited to the four-way switching valve, and may be configured to be able to realize switching of a flow direction of the refrigerant as follows, by combining a plurality of electromagnetic valves and pipes.

In the cooling mode, the flow path switching mechanism 332 switches the flow direction of the refrigerant in the refrigerant circuit 50 so that the refrigerant discharged by the compressor 330 is sent to the heat-source-side heat exchanger 340. Specifically, in the cooling mode, the flow path switching mechanism 332 connects the suction pipe 351 with the second gas-side pipe 355, and connects the discharge pipe 352 with the first gas-side pipe 353 (see a solid line in the flow path switching mechanism 332 in FIG. 2).

In the heating mode, the flow path switching mechanism 332 switches the flow direction of the refrigerant in the refrigerant circuit 50 so that the refrigerant discharged by the compressor 330 is sent to the utilization-side heat exchanger 10 of the heat exchange unit 100. Specifically, in the heating mode, the flow path switching mechanism 332 connects the suction pipe 351 with the first gas-side pipe 353, and connects the discharge pipe 352 with the second gas-side pipe 355 (see a broken line in the flow path switching mechanism 332 in FIG. 2).

(2-1-4) Heat-Source-Side Heat Exchanger

The heat-source-side heat exchanger 340 is a heat exchanger that exchanges heat between air around the heat source unit 300 and a refrigerant flowing inside the heat-source-side heat exchanger 340. The heat-source-side heat exchanger 340 is, for example, a cross-fin type fin-and-tube heat exchanger, although the type is not limited. The heat-source-side heat exchanger 340 functions as a condenser (a radiator) when the operating mode of the heat load processing system 1 is in the cooling mode. Further, the heat-source-side heat exchanger 340 functions as an evaporator when the operating mode of the heat load processing system 1 is in the heating mode.

(2-1-5) Second Expansion Mechanism

The second expansion mechanism 344 is a mechanism that expands a refrigerant flowing through the liquid-side pipe 354, to adjust a pressure and a flow rate of the refrigerant. In one or more embodiments, the second expansion mechanism 344 is an electronic expansion valve whose opening degree is adjustable. However, the second expansion mechanism 344 is not limited to the electronic expansion valve. For example, the second expansion mechanism 344 may be a temperature automatic expansion valve having a temperature sensing cylinder, or may be a capillary tube.

(2-1-6) Fan

The fan 342 is a mechanism to generate an air flow so that air passes through the heat-source-side heat exchanger 340, in order to promote heat exchange between the refrigerant and air in the heat-source-side heat exchanger 340. The fan 342 is, for example, a propeller fan, although the type is not limited.

(2-1-7) Liquid-Side Shutoff Valve

The liquid-side shutoff valve 302 is a valve that switches between communication and non-communication between the liquid-refrigerant connection pipe 52 and the liquid-side pipe 354. One end of the liquid-side shutoff valve 302 is connected with the liquid-refrigerant connection pipe 52, and another end of the liquid-side shutoff valve 302 is connected with the liquid-side pipe 354 (see FIG. 2).

(2-1-8) Gas-Side Shutoff Valve

The gas-side shutoff valve 304 is a valve that switches between communication and non-communication between the gas-refrigerant connection pipe 54 and the second gas-side pipe 355. One end of the gas-side shutoff valve 304 is connected with the gas-refrigerant connection pipe 54, and another end of the gas-side shutoff valve 304 is connected with the second gas-side pipe 355 (see FIG. 2).

(2-1-9) Heat-Source-Side Control Board

The heat-source-side control board 395 functions as a control unit 95 a together with a heat-exchange-unit side control board 95 of the heat exchange unit 100 described later. The control unit 95 a will be described later.

The heat-source-side control board 395 has various electric circuits, a microcomputer including a CPU and a memory that stores a program executed by the CPU, and the like.

(2-2) Refrigerant Connection Pipe

(2-2-1) Liquid-Refrigerant Connection Pipe

The liquid-refrigerant connection pipe 52 connects the liquid-side shutoff valve 302 of the heat source unit 300 to a liquid-side connecting port 100 a of the heat exchange unit 100, and connects the liquid-side pipe 354 of the heat source unit 300 with an in-heat-exchange-unit liquid-side pipe 56 of the heat exchange unit 100. For connecting the liquid-refrigerant connection pipe 52 and the liquid-side connecting port 100 a of the heat exchange unit 100, for example, a flare joint is used. However, a connection method between the liquid-refrigerant connection pipe 52 and the liquid-side connecting port 100 a of the heat exchange unit 100 is not limited to the connection method using the flare joint, but a connection method using a flange joint or a brazing connection may be selected, for example.

(2-2-2) Gas-Refrigerant Connection Pipe

The gas-refrigerant connection pipe 54 connects the gas-side shutoff valve 304 of the heat source unit 300 to a gas-side connecting port 100 b of the heat exchange unit 100, and connects the second gas-side pipe 355 of the heat source unit 300 with an in-heat-exchange-unit gas-side pipe 58 of the heat exchange unit 100. The gas-refrigerant connection pipe 54 and the gas-side connecting port 100 b of the heat exchange unit 100 are connected by brazing, for example. However, a connection method between the gas-refrigerant connection pipe 54 and the gas-side connecting port 100 b of the heat exchange unit 100 is not limited to the brazing connection, and a connection method using various pipe joints may be selected.

(2-3) Liquid Medium Circuit

The liquid medium circuit 400 is a circuit in which the liquid medium circulates. The liquid medium circuit 400 is configured by connecting, with a pipe, the utilization-side heat exchanger 10 of the heat exchange unit 100 and the utilization-side equipment 410.

The liquid medium circuit 400 includes the utilization-side heat exchanger 10 and the pump 60 of the heat exchange unit 100, the utilization-side equipment 410, an in-heat-exchange-unit first liquid medium pipe 66, an in-heat-exchange-unit second liquid medium pipe 68, an in-heat-exchange-unit connection pipe 67, a first connection pipe 422, and a second connection pipe 424.

The utilization-side heat exchanger 10 and the pump 60 of the heat exchange unit 100 will be described later.

As described above, the utilization-side equipment 410 is, for example, an air handling unit or a fan coil unit. Further, for example, as described above, the utilization-side equipment 410 may be manufacturing equipment that cools or heats a manufacturing device or a manufactured product by using a liquid medium cooled or heated by the heat exchange unit 100, or may be a tank that stores the liquid medium cooled or heated by the heat exchange unit 100.

The in-heat-exchange-unit first liquid medium pipe 66 is a pipe that connects a liquid medium inlet 62 of the heat exchange unit 100 and the utilization-side heat exchanger 10 (particularly, a first heat exchanger 10 a described later). In the in-heat-exchange-unit first liquid medium pipe 66, the pump 60 is arranged.

The in-heat-exchange-unit second liquid medium pipe 68 is a pipe that connects the utilization-side heat exchanger 10 (particularly, a second heat exchanger 10 b described later) and a liquid medium outlet 64 of the heat exchange unit 100.

The in-heat-exchange-unit connection pipe 67 is a pipe that connects the first heat exchanger 10 a and the second heat exchanger 10 b, which will be described later.

The first connection pipe 422 is a pipe that connects the utilization-side equipment 410 and the liquid medium inlet 62 of the heat exchange unit 100. Although a connection method is not limited, the first connection pipe 422 is connected to the liquid medium inlet 62 of the heat exchange unit 100, for example, by a flange joint. Alternatively, the first connection pipe 422 may be screwed or welded to be connected to the liquid medium inlet 62 of the heat exchange unit 100.

The second connection pipe 424 is a pipe that connects the liquid medium outlet 64 of the heat exchange unit 100 and the utilization-side equipment 410. Although a connection method is not limited, the second connection pipe 424 is connected to the liquid medium outlet 64 of the heat exchange unit 100, for example, by a flange joint. Alternatively, the second connection pipe 424 may be screwed or welded to be connected to the liquid medium outlet 64 of the heat exchange unit 100.

When the pump 60 is operated, the liquid medium flows through the liquid medium circuit 400 as follows.

The liquid medium having flowed out from the utilization-side equipment 410 flows through the first connection pipe 422 toward the liquid medium inlet 62 of the heat exchange unit 100. The liquid medium having flowed into the heat exchange unit 100 from the liquid medium inlet 62 passes through the in-heat-exchange-unit first liquid medium pipe 66 to flow into the utilization-side heat exchanger 10. When the liquid medium passes through the utilization-side heat exchanger 10, the liquid medium is cooled or heated by exchanging heat with the refrigerant flowing through the refrigerant circuit 50. The liquid medium cooled or heated by the utilization-side heat exchanger 10 flows out from the utilization-side heat exchanger 10, and flows through the in-heat-exchange-unit second liquid medium pipe 68 toward the liquid medium outlet 64. The liquid medium having flowed out of the heat exchange unit 100 from the liquid medium outlet 64 flows through the second connection pipe 424 to flow into the utilization-side equipment 410.

(2-4) Heat Exchange Unit

The heat exchange unit 100 is a unit that exchanges heat between a liquid medium sent to the utilization-side equipment 410 and a refrigerant, to perform at least one of cooling and heating of the liquid medium. As described above, the heat exchange unit 100 of one or more embodiments is a unit that exchanges heat between the liquid medium sent to the utilization-side equipment 410 and the refrigerant, to perform both cooling and heating of the liquid medium.

Note that, when the heat exchange unit 100 is a unit intended only for cooling the liquid medium, the heat source unit 300 need not have the flow path switching mechanism 332. Further, when the heat exchange unit 100 is a unit intended only for heating the liquid medium, in particular, in a case of not performing a reverse cycle defrost operation for supplying the refrigerant discharged from the compressor 330 to the heat-source-side heat exchanger 340 to remove frost attached to the heat-source-side heat exchanger 340, the heat source unit 300 need not have the flow path switching mechanism 332 described above.

The heat exchange unit 100 mainly includes the casing 90, a drain pan 80, the utilization-side heat exchanger 10, a first expansion mechanism 20, the pump 60, a gas detection sensor 70, and an electric component box 92 (see FIGS. 4 to 7).

The heat exchange unit 100 has the first expansion mechanisms 20 of the same number as the number of the heat source units 300 (the same number as the number of the refrigerant circuits 50 including the heat source unit 300 and the heat exchange unit 100). In one or more embodiments, the heat exchange unit 100 has four first expansion mechanisms 20.

The heat exchange unit 100 of one or more embodiments has two utilization-side heat exchangers 10 (the first heat exchanger 10 a and the second heat exchanger 10 b) connected in series in the liquid medium circuit 400. However, the number of utilization-side heat exchangers 10 is an example, and is not limited to two. For example, the heat exchange unit 100 may have the utilization-side heat exchangers 10 of the same number (here, four) as the number of the heat source units 300 connected in series in the liquid medium circuit 400. Further, for example, the heat exchange unit 100 may have only one piece of utilization-side heat exchanger 10, the utilization-side heat exchanger 10 may be connected to all the (here, four) heat source units 300, and the refrigerant circuits 50 of the same number as the number of the heat source units 300 may be configured. Further, the heat exchange unit 100 may have a plurality of utilization-side heat exchangers 10 connected in parallel in the liquid medium circuit 400.

Further, the heat exchange unit 100 of one or more embodiments has one pump 60. However, without limiting to this, the heat exchange unit 100 may have a plurality of pumps 60 connected in series or in parallel in the liquid medium circuit 400.

(2-4-1) Casing

The casing 90 accommodates various components and various devices of the heat exchange unit 100, including the drain pan 80, the utilization-side heat exchanger 10, the first expansion mechanism 20, the pump 60, the gas detection sensor 70, and the electric component box 92. A top surface and side surfaces of the heat exchange unit 100 are surrounded by a top panel and side plates (see FIG. 1).

In a lower part of the casing 90 (see FIG. 6), the drain pan 80 is arranged. Above the drain pan 80, the utilization-side heat exchanger 10 and the pump 60 are arranged (see FIG. 6). The first expansion mechanism 20 is arranged near an upper end of the utilization-side heat exchanger 10, in front of the utilization-side heat exchanger 10 (see FIG. 6). The electric component box 92 is arranged at an upper front face side of the casing 90 (see FIG. 7). The electric component box 92 is arranged above the utilization-side heat exchanger 10 and the pump 60 (see FIG. 6).

On the front face of the casing 90, an opening 91 a for maintenance is provided (see FIG. 6). Further, on a back face of the casing 90, an opening 91 b for maintenance is provided (see FIG. 9). The openings 91 a and 91 b of the casing 90 are closed by side plates of the casing 90 normally, that is, during operation of the heat load processing system 1. By removing the side plates of the casing 90 provided on the openings 91 a and 91 b, components and devices inside the casing 90 can be maintained or replaced.

On the front face of the casing 90 (in a lower right part of the casing 90 in FIG. 4), four liquid-side connecting ports 100 a and four gas-side connecting ports 100 b of the heat exchange unit 100 are provided. To each liquid-side connecting port 100 a, the liquid-refrigerant connection pipe 52 is connected (see FIG. 2). To each gas-side connecting port 100 b, the gas-refrigerant connection pipe 54 is connected (see FIG. 2). Further, on the back face of the casing 90, the liquid medium inlet 62 and the liquid medium outlet 64 of the heat exchange unit 100 are provided (see FIGS. 5 and 7). To the liquid medium inlet 62, the first connection pipe 422 is connected (see FIG. 2). To the liquid medium outlet 64, the second connection pipe 424 is connected (see FIG. 2).

Note that positions of the liquid-side connecting port 100 a, the gas-side connecting port 100 b, the liquid medium inlet 62, and the liquid medium outlet 64 are not limited to the positions drawn in the figure, and may be changed as appropriate.

(2-4-2) Drain Pan

The drain pan 80 will be described with reference to FIGS. 5 to 10.

Note that FIG. 8 is a schematic plan view of the drain pan 80. FIG. 9 is a schematic rear view of a part of the casing 90 (near the drain pan 80) and the drain pan of FIG. 8. FIG. 10 is a schematic right side view of the drain pan 80.

The drain pan 80 is arranged in a lower part of the casing 90. In particular, in one or more embodiments, the drain pan 80 is arranged in a lowermost part of the casing 90. The drain pan 80 is arranged below the utilization-side heat exchanger 10. Further, the drain pan 80 is arranged below the pump 60. The drain pan 80 receives condensation water generated on the utilization-side heat exchanger 10, the pump 60, pipes through which the liquid medium and the refrigerant flow, and the like. When the heat exchange unit 100 is installed outdoors, rainwater or the like also flows into the drain pan 80. Moreover, the drain pan 80 may have a function as a bottom plate of the casing 90.

The drain pan 80 may be arranged lower than: at least a part of the refrigerant pipe 57 described later; at least a part of the in-heat-exchange-unit first liquid medium pipe 66, the in-heat-exchange-unit connection pipe 67, and the in-heat-exchange-unit second liquid medium pipe 68; the utilization-side heat exchanger 10; and the pump 60. In one or more embodiments, the drain pan 80 may be arranged so as to surround most of a lower part of the heat exchange unit 100. For example, in top view, the drain pan 80 covers 80% or more of an area of the heat exchange unit 100 (a bottom area of the casing 90).

The drain pan 80 has a bottom plate 82 and a side wall 84. The bottom plate 82 has a substantially rectangular shape in plan view (see FIGS. 8 to 10). The side wall 84 extends upward from an outer peripheral edge of the bottom plate 82 (see FIGS. 9 and 10). Although not limited, a height from the bottom plate 82 to the upper end part 84 a of the side wall 84 is about 80 mm at a highest part. That is, a height from an outer peripheral edge on a rear side of the bottom plate 82 to the upper end part 84 a of the side wall 84 is about 80 mm.

A space formed above the bottom plate 82 of the drain pan 80 and below an upper end part 84 a of the side wall 84 of the drain pan 80 is referred to here as an internal space Si of the drain pan 80. The internal space Si of the drain pan 80 is a space in which the bottom plate 82 and the side wall 84 surround a lower part and a side surface, and an upper part is open. In other words, the internal space Si of the drain pan 80 is a space surrounded by the bottom plate 82, the side wall 84, and a virtual plane passing through the upper end part 84 a of the side wall 84. Condensation water having fallen into the internal space Si of the drain pan 80 is once received by the internal space Si, and discharged from a drain port provided in the drain pan 80. The drain port is an opening to discharge water in the internal space Si of the drain pan 80. The drain port is provided on at least one of the bottom plate 82 and the side wall 84 of the drain pan 80. In one or more embodiments, a drain pipe 86 is attached to the side wall 84 arranged on a rear side of the drain pan 80 so as to communicate with the internal space Si of the drain pan 80, and an end part of the drain pipe 86 on the internal space Si side functions as a drain port 86 a (see FIG. 8). The drain port 86 a is provided in a center of the side wall 84 arranged on the rear side of the drain pan 80. In other words, the drain pipe 86 is attached to a center of the side wall 84 arranged on the rear side of the drain pan 80. The drain pipe 86 is attached to a lower part of the side wall 84 arranged on the rear side of the drain pan 80 (see FIG. 9).

Note that, in one or more embodiments, the drain pan 80 is provided with only one drain port, but the configuration is not limited to this, and drain ports may be provided at a plurality of places. Further, the drain port need not be formed by a pipe fixed to the bottom plate 82 or the side wall 84 of the drain pan 80, but the drain port may be provided by simply forming a hole in the bottom plate 82 or the side wall 84 of the drain pan 80.

The bottom plate 82 of the drain pan 80 has an inclined part 82 a that is inclined with respect to a horizontal plane. In particular, in one or more embodiments, the entire bottom plate 82 is inclined with respect to the horizontal plane, and the entire bottom plate 82 functions as the inclined part 82 a. In one or more embodiments, the inclined part 82 a is inclined so as to be lowered from a front side to a rear side, and has an upper end 82 aa on the front side and a lower end 82 ab on the rear side (see FIG. 10). That is, in one or more embodiments, the bottom plate 82 is lowered toward the side wall 84 arranged on the rear side of the drain pan 80 provided with the drain port 86 a, and water is easily discharged from the internal space Si of the drain pan 80 through the drain port 86 a.

Note that the bottom plate 82 of the drain pan 80 need not be entirely inclined with respect to the horizontal plane as in the above-described embodiments. That is, the bottom plate 82 may have the inclined part 82 a only partially. For example, in the bottom plate 82 of the drain pan 80, a region where condensation water is unlikely to fall need not be provided with an inclination.

(2-4-3) Utilization-Side Heat Exchanger

The utilization-side heat exchanger 10 includes the first heat exchanger 10 a and the second heat exchanger 10 b.

Note that, in the following description, features common to the first heat exchanger 10 a and the second heat exchanger 10 b will be described as a description of the utilization-side heat exchanger 10 without distinguishing as the first heat exchanger 10 a or the second heat exchanger 10 b.

The utilization-side heat exchanger 10 exchanges heat between the refrigerant and the liquid medium. In one or more embodiments, the utilization-side heat exchanger 10 is a plate-type heat exchanger. However, a type of the utilization-side heat exchanger 10 is not limited to the plate-type heat exchanger, and it is sufficient to appropriately select a heat exchanger of a type that can be used as a heat exchanger between the refrigerant and the liquid medium.

To the first heat exchanger 10 a and the second heat exchanger 10 b, two in-heat-exchange-unit liquid-side pipes 56 and two in-heat-exchange-unit gas-side pipes 58 are individually connected. Further, to the first heat exchanger 10 a, the in-heat-exchange-unit first liquid medium pipe 66 and the in-heat-exchange-unit connection pipe 67 are connected. To the second heat exchanger 10 b, the in-heat-exchange-unit connection pipe 67 and the in-heat-exchange-unit second liquid medium pipe 68 are connected. The in-heat-exchange-unit connection pipe 67 is a pipe that connects a liquid medium flow path (not illustrated) in the first heat exchanger 10 a with a liquid medium flow path in the second heat exchanger 10 b.

When the pump 60 is operated, the liquid medium passes through the first connection pipe 422 and the in-heat-exchange-unit first liquid medium pipe 66 to flow into the first heat exchanger 10 a, and passes through the liquid medium flow path (not illustrated) in the first heat exchanger 10 a to flow out to the in-heat-exchange-unit connection pipe 67. The liquid medium having flowed out from the first heat exchanger 10 a to the in-heat-exchange-unit connection pipe 67 passes through the in-heat-exchange-unit connection pipe 67 to flow into the second heat exchanger 10 b. The liquid medium having flowed into the second heat exchanger 10 b passes through the liquid medium flow path (not illustrated) in the second heat exchanger 10 b, and further passes through the in-heat-exchange-unit second liquid medium pipe 68 and the second connection pipe 424, to be sent to the utilization-side equipment 410.

When the operating mode of the heat load processing system 1 is in the cooling mode, to each utilization-side heat exchanger 10, the refrigerant flows from the in-heat-exchange-unit liquid-side pipe 56 into a refrigerant flow path (not illustrated) in each utilization-side heat exchanger 10. The liquid medium flowing through the liquid medium flow path (not illustrated) in each utilization-side heat exchanger 10 is cooled by exchanging heat with the refrigerant flowing through the refrigerant flow path (not illustrated) in each utilization-side heat exchanger 10. The refrigerant having flowed through the refrigerant flow path (not illustrated) in each utilization-side heat exchanger 10 flows into the in-heat-exchange-unit gas-side pipe 58, and passes through the gas-refrigerant connection pipe 54 to flow into the second gas-side pipe 355 of the heat source unit 300.

Whereas, when the operating mode of the heat load processing system 1 is in the heating mode, to each utilization-side heat exchanger 10, the refrigerant flows from the in-heat-exchange-unit gas-side pipe 58 into the refrigerant flow path (not illustrated) in each utilization-side heat exchanger 10. The liquid medium flowing through the liquid medium flow path (not illustrated) in each utilization-side heat exchanger 10 is heated by exchanging heat with the refrigerant flowing through the refrigerant flow path (not illustrated) in each utilization-side heat exchanger 10. The refrigerant having flowed through the refrigerant flow path (not illustrated) in each utilization-side heat exchanger 10 flows into the in-heat-exchange-unit liquid-side pipe 56, and passes through the liquid-refrigerant connection pipe 52 to flow into the liquid-side pipe 354 of the heat source unit 300.

(2-4-4) First Expansion Mechanism

The first expansion mechanism 20 is a mechanism that expands a refrigerant flowing through the in-heat-exchange-unit liquid-side pipe 56, to adjust a pressure and a flow rate of the refrigerant.

In one or more embodiments, the first expansion mechanism 20 is an electronic expansion valve whose opening degree is adjustable. The electronic expansion valve as the first expansion mechanism 20 is arranged near an upper end of the utilization-side heat exchanger 10, in front of the utilization-side heat exchanger 10. However, the first expansion mechanism 20 is not limited to the electronic expansion valve. For example, the first expansion mechanism 20 may be a temperature automatic expansion valve having a temperature sensing cylinder, or may be a capillary tube.

(2-4-5) Pump

The pump 60 is a pump that sends the liquid medium to the utilization-side equipment 410. The pump 60 is arranged in the in-heat-exchange-unit first liquid medium pipe 66.

The pump 60 is, for example, a constant speed centrifugal pump. However, the pump 60 is not limited to the centrifugal pump, and a type of the pump 60 may be appropriately selected. Further, the pump 60 may be, for example, a pump having a variable flow rate.

Note that, in one or more embodiments, the pump 60 is arranged upstream of the utilization-side heat exchanger 10 in a flow direction of the liquid medium in the liquid medium circuit 400, in other words, in the in-heat-exchange-unit first liquid medium pipe 66. However, without limiting to this, the pump 60 may be arranged downstream of the utilization-side heat exchanger 10 in the flow direction of the liquid medium in the liquid medium circuit 400, in other words, in the in-heat-exchange-unit second liquid medium pipe 68.

(2-4-6) Gas Detection Sensor

The gas detection sensor 70 is a sensor that detects the presence or absence of refrigerant gas in the internal space Si of the drain pan 80. In one or more embodiments, the gas detection sensor 70 may have a detection element 72, and may detect the presence or absence of refrigerant gas at a place where the detection element 72 is arranged.

The detection element 72 is, for example, a semiconductor-type sensor element. Electrical conductivity of the semiconductor-type detection element changes depending on a state where no refrigerant gas is present in the surroundings or a state where refrigerant gas is present. The gas detection sensor 70 includes a detection circuit (not illustrated) that is electrically connected to the detection element 72, and detects the presence or absence of the refrigerant gas by detecting a change in electrical conductivity of the detection element 72 with the detection circuit.

However, the detection element 72 is not limited to the semiconductor-type element, and may be any element capable of detecting the refrigerant gas. For example, the gas detection sensor 70 may include an infrared light source (not illustrated) and an infrared detection element as the detection element 72, and may detect the presence or absence of the refrigerant gas by detecting a change in a detection amount of infrared rays of the detection element 72, which changes depending on the presence or absence of refrigerant gas, with a detection circuit that is electrically connected to the detection element 72.

As described above, since the refrigerant gas has a higher density than air, the refrigerant gas easily moves to a lower position when the refrigerant leaks in the heat exchange unit 100. Therefore, leaked refrigerant gas tends to accumulate in the internal space Si of the drain pan 80. In particular, in one or more embodiments, since the drain pan 80 covers most of the lower part of the heat exchange unit 100, for example, 80% or more of the bottom area of the casing 90 in top view, leaked refrigerant gas tends to accumulate in the internal space Si of the drain pan 80. Therefore, the detection element 72 of the gas detection sensor 70 may be arranged in the internal space Si of the drain pan 80 located at the lower part in the casing 90. In one or more embodiments, the detection element 72 may be arranged on the lower end 82 ab side of the inclined part 82 a of the bottom plate 82 of the drain pan 80 (in one or more embodiments, a rear end side of the bottom plate 82). Further, the detection element 72 may be arranged near the drain port 86 a, which is a discharge port of water from the internal space Si of the drain pan 80.

In one or more embodiments, the detection element 72 of the gas detection sensor 70 is arranged on the lower end 82 ab side of the inclined part 82 a in the internal space Si of the drain pan 80 (see FIG. 10). Further, the detection element 72 of the gas detection sensor 70 is arranged at a position adjacent to the drain port 86 a provided on the side wall 84 on the rear side of the drain pan 80 (see FIGS. 8 to 10). By arranging the detection element 72 at such a position where refrigerant gas is likely to accumulate, highly reliable refrigerant leakage detection is possible.

Note that the position where the detection element 72 of the gas detection sensor 70 is arranged is an example, and is not limited to the position drawn in FIGS. 8 to 10.

For example, the position where the detection element 72 of the gas detection sensor 70 is arranged may be, for example, away from the drain port 86 a, in the vicinity of the side wall 84 on the rear side of the drain pan 80 (on the lower end 82 ab side of the inclined part 82 a).

In addition, for example, when a place is specified where there is a relatively high possibility of leakage of the refrigerant gas, the detection element 72 of the gas detection sensor 70 may be arranged near the place where the possibility of leakage of the refrigerant gas is relatively high, in the internal space Si of the drain pan 80. In this case, the detection element 72 of the gas detection sensor 70 may be arranged at a place other than the lower end 82 ab side of the inclined part 82 a (for example, the upper end 82 aa side of the inclined part 82 a).

Further, for example, the detection element 72 of the gas detection sensor 70 need not be arranged in the internal space Si of the drain pan 80. For example, the gas detection sensor 70 may use the detection element 72 arranged very close to the upper end part 84 a, at a position higher than the upper end part 84 a of the side wall 84 of the drain pan 80, to detect the presence or absence of the refrigerant gas in the internal space Si of the drain pan 80. In addition, the gas detection sensor 70 may use the detection element 72 arranged at another place outside the internal space Si of the drain pan 80 and where the gas in the internal space Si of the drain pan 80 can be detected, to detect the presence or absence of the refrigerant gas in the internal space Si of the drain pan 80. For example, the place outside the internal space Si of the drain pan 80 and where the gas in the internal space Si of the drain pan 80 can be detected includes an opening on an opposite side of the drain port 86 a of the drain pipe 86.

Further, the detection element 72 of the gas detection sensor 70 may be arranged below an electric component that can be an ignition source (see FIGS. 6 and 7). By arranging the detection element 72 below the electric component that can be an ignition source, refrigerant leakage is easily detected before the refrigerant gas reaches a height position of the electric component that can be an ignition source from the bottom side of the casing 90, even if the refrigerant leaks in the heat exchange unit 100.

Note that the electric component that can be an ignition source include an electric component that may generate an electric spark. In one or more embodiments, the electric components that can be an ignition source include: the electric components 93 such as an electromagnetic switch, a contactor, and a relay accommodated in the electric component box 92, which will be described later; an electronic expansion valve as an example of the first expansion mechanism 20; and the terminal box 61 of the pump 60. The terminal box 61 of the pump 60 is connected with an electric wire 61 a for supply of electric power to a motor 60 a of the pump 60.

Further, although it is not mounted on the heat exchange unit 100 of the above-described embodiments, a heater may be arranged in the heat exchange unit 100 when the heat exchange unit 100 is installed in a cold region. Depending on specifications, the heater can be hot enough to be an ignition source. In one or more embodiments, the electric component that can become hot enough to be an ignition source may also be arranged above the detection element 72 of the gas detection sensor 70.

Further, the detection element 72 of the gas detection sensor 70 may be arranged below the liquid-side connecting port 100 a and the gas-side connecting port 100 b of the heat exchange unit 100, which is where refrigerant is relatively likely to leak (see FIGS. 6 and 7). Whereas, the electric component that can be an ignition source may be arranged above the liquid-side connecting port 100 a and the gas-side connecting port 100 b of the heat exchange unit 100. Such an arrangement allows refrigerant leakage to be easily detected before the refrigerant gas reaches a height position of the electric component that can be an ignition source from the bottom side of the casing 90, even if the refrigerant leaks at the liquid-side connecting port 100 a or the gas-side connecting port 100 b of the heat exchange unit 100.

Moreover, the electric component that can be an ignition source (in one or more embodiments: the electric components 93 such as an electromagnetic switch, a contactor, and a relay accommodated in the electric component box 92; an electronic expansion valve as an example of the first expansion mechanism 20; and the terminal box 61 of the pump 60) may be arranged at a position that is 300 mm or more higher than a bottom of the casing 90 (see FIGS. 6 and 7). By arranging the electric component that can be an ignition source at such a height position, the possibility of ignition with the electric component in the casing 90 as the ignition source is reduced even if the refrigerant leaks.

Further, if the refrigerant leaks, there is a high possibility that the refrigerant leaks from the utilization-side heat exchanger 10, or a refrigerant pipe 57 including the in-heat-exchange-unit liquid-side pipe 56 and the in-heat-exchange-unit gas-side pipe 58. Therefore, the detection element 72 of the gas detection sensor 70 may be arranged at the following position.

In plan view, an inside of the casing 90 is sectioned into at least a pump arrangement area A1 where the pump 60 is arranged, and a refrigerant side area A2 where the refrigerant pipe 57 through which the refrigerant flows or the utilization-side heat exchanger 10 is arranged (see FIGS. 5 and 8). That is, in plan view, the pump arrangement area A1 and the refrigerant side area A2 exist inside the casing 90. As shown in FIG. 8, the detection element 72 of the gas detection sensor 70 may be arranged closer to the refrigerant side area A2 than the pump arrangement area A1.

Further, from the viewpoint of maintenance, the detection element 72 of the gas detection sensor 70 may be arranged in a space near the opening 91 b for maintenance, in the casing 90. The space near the opening 91 b is a space accessible to a worker from the opening 91 b. For example, the space near the opening 91 b is a space within hand reach from the opening 91 b (for example, a space within 50 cm from the opening 91 b). An arrangement of the detection element 72 of the gas detection sensor 70 at such a position allows the detection element 72 to be easily replaced and inspected by removing the side plate of the casing 90 that closes the opening 91 b.

Further, since the detection element 72 of the gas detection sensor 70 detects the refrigerant gas, it may be that the detection element 72 is arranged at a position that is less likely to be immersed even if condensation water accumulates in the internal space Si of the drain pan 80.

For example, in one or more embodiments, the heat exchange unit 100 may have a float 88 that is arranged in the internal space Si of the drain pan 80, and the detection element 72 may be attached to an upper surface 88 a or a side surface 88 b of the float 88. The float 88 is a member configured to float on a water surface when condensation water accumulates in the internal space Si of the drain pan 80.

A structure of the float 88 will be more specifically described. For example, specifically, the float 88 has a main body 881, and a swing shaft 882 that is swingably supported by a support part (not illustrated) provided on the side wall 84 of the drain pan 80 or a frame (not illustrated) of the casing 90 (see FIGS. 11A and 11B). The main body 881 is configured to float on water. The detection element 72 of the gas detection sensor 70 may be attached to the upper surface 88 a of the float 88 (an upper surface of the main body 881) as shown in FIG. 11A, or may be attached to the side surface 88 b (a side surface of the main body 881) of the float 88 as shown in FIG. 11B. When there is no water in the drain pan 80, the main body 881 of the float 88 is located at a first position. Although not limited, the main body 881 of the float 88 located at the first position is in contact with the bottom plate 82 of the drain pan 80, as shown by solid lines in FIGS. 11A and 11B. Whereas, when water accumulates in the drain pan 80, the main body 881 of the float 88 swings around the swing shaft 882 and floats due to buoyancy as shown by two-dot chain lines in FIGS. 11A and 11B. Such a configuration facilitates suppression of immersion of the detection element 72 of the gas detection sensor 70, even when condensation water accumulates in the internal space Si of the drain pan 80. Therefore, even if, for example, the drain pipe 86 is clogged for some reason and water is not discharged from the drain port 86 a, the gas refrigerant can be detected by the gas detection sensor 70 when the refrigerant leaks.

Alternatively, the heat exchange unit 100 need not have the float 88. Then, the detection element 72 of the gas detection sensor 70 may be directly attached to the side wall 84 of the drain pan 80 or the frame (not illustrated) of the casing 90. In this case, the detection element 72 of the gas detection sensor 70 may be arranged at a position that is less likely to be immersed, for example, a position higher than the drain port 86 a in the internal space Si of the drain pan 80, as shown by reference numeral 72 a in FIG. 9.

(2-4-7) Electric Component Box

The electric component box 92 is a case that accommodates various electric components. The electric component box 92 accommodates the heat-exchange-unit side control board 95, a power source terminal block (not illustrated), and the electric components 93 such as an electromagnetic switch, a contactor, and a relay (see FIG. 2). The electric component 93 need not include all of the electromagnetic switch, the contactor, and the relay, but may include any of the electromagnetic switch, the contactor, and the relay. Note that the electric components accommodated in the electric component box 92 are not limited to those exemplified, and various electric components are accommodated as needed.

The heat-exchange-unit side control board 95 functions as the control unit 95 a together with the heat-source-side control board 395 of the heat source unit 300. The heat-exchange-unit side control board 95 has various electric circuits, a microcomputer including a CPU and a memory that stores a program executed by the CPU, and the like.

The control unit 95 a controls an operation of each unit of the heat load processing system 1.

The control unit 95 a is electrically connected to various devices of the heat source unit 300 and the heat exchange unit 100. The various devices of the heat source unit 300 and the heat exchange unit 100 connected to the control unit 95 a include: the compressor 330, the flow path switching mechanism 332, the second expansion mechanism 344, and the fan 342 of the heat source unit 300; and the first expansion mechanism 20 and the pump 60 of the heat exchange unit 100. Further, the control unit 95 a is communicably connected to various sensors provided to the heat source unit 300 and the heat exchange unit 100, and receives measured values from the various sensors (not illustrated). The various sensors provided to the heat exchange unit 100 include, but not limited to, for example, a temperature sensor that is provided in the in-heat-exchange-unit liquid-side pipe 56 or the in-heat-exchange-unit gas-side pipe 58 and measures a temperature of the refrigerant, a pressure sensor provided in the in-heat-exchange-unit liquid-side pipe 56, a temperature sensor provided in the in-heat-exchange-unit first liquid medium pipe 66, the in-heat-exchange-unit connection pipe 67, and the in-heat-exchange-unit second liquid medium pipe 68 and measures a temperature of the liquid medium, and the like. Further, the various sensors provided to the heat source unit 300 include, but not limited to, for example, a temperature sensor that is provided in the suction pipe 351 and measures a suction temperature, a temperature sensor that is provided in the discharge pipe 352 and measures a discharge temperature, and a pressure sensor that is provided in the discharge pipe 352 and measures a discharge pressure. Further, the control unit 95 a is communicably connected to the gas detection sensor 70 of the heat source unit 300.

The control unit 95 a controls an operation of various devices of the heat source unit 300 and the heat exchange unit 100 in response to an operation or stop command given from an operation device (not illustrated). Further, the control unit 95 a controls a state of the flow path switching mechanism 332 of the heat source unit 300 in accordance with an operating mode (the cooling mode or the heating mode) of the heat load processing system 1. In addition, the control unit 95 a controls an operation of various devices of the heat source unit 300 and the heat exchange unit 100 such that a liquid medium is cooled or heated to reach a predetermined target temperature and flows out from the liquid medium outlet 64 of the heat exchange unit 100. Note that an operating principle of a vapor compression refrigerator is generally well known, and thus a description thereof is omitted here. In addition, when the gas detection sensor 70 detects leakage of refrigerant gas, the control unit 95 a controls various devices such that various devices of the heat source unit 300 and the heat exchange unit 100 perform a predetermined operation at a time of leakage.

(3) Characteristics

(3-1)

The heat exchange unit 100 of the above-described embodiments exchanges heat between a liquid medium sent to utilization-side equipment 410 and the refrigerant, to perform at least one of cooling and heating of the liquid medium. The heat exchange unit 100 includes the utilization-side heat exchanger 10 as an example of a heat exchanger, the casing 90, the drain pan 80, and the gas detection sensor 70. The gas detection sensor 70 is an example of a first gas detection sensor. The utilization-side heat exchanger 10 exchanges heat between the flammable refrigerant and the liquid medium. The casing 90 accommodates the utilization-side heat exchanger 10. The drain pan 80 is arranged below the utilization-side heat exchanger 10, in a lower part of the casing 90. The drain pan 80 has the bottom plate 82 and the side wall 84 extending upward from the bottom plate 82. The gas detection sensor 70 detects the presence or absence of refrigerant gas in the internal space Si of the drain pan 80, the internal space Si being located above the bottom plate 82 of the drain pan 80 and below the upper end part of the side wall 84 of the drain pan 80.

The refrigerant gas is usually heavier than air. Therefore, when the refrigerant leaks, the leaked refrigerant gas moves downward. Therefore, in this heat exchange unit 100, leaked refrigerant gas tends to accumulate in the drain pan 80 that is arranged in the lower part of the casing 90 and receives dew condensation water generated on the pipe, the heat exchanger, and the like.

Here, highly reliable leakage detection of refrigerant gas is possible by detecting the presence or absence of refrigerant gas in the internal space Si of the drain pan 80 where leaked refrigerant gas tends to accumulate.

In one or more embodiments, the gas detection sensor 70 may have, as an example of a first detection element, the detection element 72 that is arranged in the internal space Si of the drain pan 80, and may detect the presence or absence of the refrigerant gas at a place where the detection element 72 is arranged.

Here, by arranging the detection element 72 of the gas detection sensor 70 in the internal space Si of the drain pan 80 where leaked refrigerant gas tends to accumulate, highly reliable refrigerant leakage detection is possible.

(3-2)

In the heat exchange unit 100 of the above-described embodiments, the bottom plate 82 of the drain pan 80 has the inclined part 82 a that is inclined with respect to a horizontal plane. The detection element 72 is arranged on a lower end side of the inclined part 82 a.

Here, since the detection element of the gas detection sensor 70 is arranged on the lower end side of the inclined part 82 a where the refrigerant gas tends to accumulate, highly reliable refrigerant leakage detection is possible.

(3-3)

In the heat exchange unit 100 of the above-described embodiments, at least one of the bottom plate 82 or the side wall 84 of the drain pan 80 is provided with the drain port 86 a for discharge of water in the internal space Si of the drain pan 80. The detection element 72 is provided near (e.g., adjacent to) the drain port 86 a.

Here, since the detection element 72 of the gas detection sensor 70 is arranged in a position where water is easily discharged, in other words, arranged near the drain port 86 a of the drain pan 80 where water (fluid) easily flows, highly reliable refrigerant leakage detection is possible.

(3-4)

The heat exchange unit 100 of the above-described embodiments includes the float 88 arranged in the internal space Si of the drain pan 80. The detection element 72 is attached to the upper surface 88 a or the side surface 88 b of the float 88.

Here, since the detection element 72 of the gas detection sensor 70 is attached to the upper surface 88 a or the side surface 88 b of the float 88, it is possible to detect refrigerant leakage even when water accumulates in the drain pan 80.

(3-5)

In the heat exchange unit 100 of the above-described embodiments, the casing 90 is formed with the opening 91 b for maintenance. The detection element 72 is arranged in a space near (e.g., adjacent to) the opening 91 b.

Here, since the detection element 72 of the gas detection sensor 70 is arranged in the space near the opening 91 b for maintenance, the detection element 72 of the gas detection sensor 70 can be easily inspected or replaced.

(3-6)

The heat exchange unit 100 of the above-described embodiments includes the pump 60. The pump 60 is arranged inside the casing 90. The pump 60 sends a liquid medium to the utilization-side equipment 410. An inside of the casing 90 is sectioned into at least the pump arrangement area A1 and the refrigerant side area A2 in plan view. In the pump arrangement area A1, the pump 60 is arranged. In the refrigerant side area A2, the refrigerant pipe 57 through which the refrigerant flows or the utilization-side heat exchanger 10 is arranged. The detection element 72 is arranged closer to the refrigerant side area A2 than the pump arrangement area A1 in plan view.

Here, since the detection element 72 of the gas detection sensor 70 is arranged, inside the casing 90, relatively close to the refrigerant pipe 57 through which the refrigerant flows and the utilization-side heat exchanger 10, highly reliable refrigerant leakage detection is possible.

(4) Modified Examples (4-1) Modified Example 1A

The heat exchange unit 100 of the above-described embodiments includes the pump 60, but the configuration is not limited to this. The pump 60 may be installed outside the casing 90 separately from the heat exchange unit 100.

(4-2) Modified Example 1B

The heat exchange unit 100 may further have an auxiliary gas detection sensor 270 having a detection element 272 arranged outside the casing 90 (see FIG. 12), in addition to the gas detection sensor 70 having the detection element 72 arranged in the internal space Si of the drain pan 80.

The auxiliary gas detection sensor 270 is a sensor that detects the presence or absence of refrigerant gas at a place where the detection element 272 is arranged. The auxiliary gas detection sensor 270 is similar to the gas detection sensor 70 except for the installation place of the detection element 272.

Since the heat exchange unit 100 has the auxiliary gas detection sensor 270, the auxiliary gas detection sensor 270 can detect refrigerant gas even if the refrigerant gas flows out of the casing 90, which enhances safety.

Since the refrigerant gas has a higher density than that of air as described above, the detection element 272 of the auxiliary gas detection sensor 270 may be arranged near a floor surface FL of a unit installation space (for example, the machine room R) where the heat exchange unit 100 is installed. For example, the detection element 272 may be arranged at a position lower than a height position of 300 mm above the floor surface FL of the machine room R. For example, in some cases, the heat exchange unit 100 may be installed on a foundation (a stand) 2 provided on the floor surface FL in the machine room R (see FIG. 12). In such a case, the detection element 272 of the auxiliary gas detection sensor 270 may be arranged near the floor surface FL of the machine room R. The detection element 272 of the auxiliary gas detection sensor 270 may be arranged at a height position up to 300 mm above the floor surface FL of the machine room R. In this case, the detection element 272 of the auxiliary gas detection sensor 270 may be arranged at a position lower than the bottom of the casing 90 of the heat exchange unit 100.

(4-3) Modified Example 1C

In the above-described embodiments, a liquid medium cooled or heated by the heat exchange unit 100 circulates in the liquid medium circuit 400, but the configuration is not limited to this. For example, when the cooled or heated liquid medium itself is used directly, the liquid medium sent to the utilization-side equipment 410 (for example, a tank) may be used as it is without circulating in the liquid medium circuit 400.

Second Embodiment (1) Overall Configuration

A heat exchange unit 200 according to one or more embodiments and a heat load processing system 201 including the heat exchange unit 100 will be described with reference to the drawings.

FIG. 13 is a perspective view of the heat exchange unit 200. FIG. 14 is a schematic configuration diagram of the heat load processing system 201 including the heat exchange unit 200. Note that the heat exchange unit 200 has three systems of an identical refrigerant circuit 150, but only one system of the refrigerant circuit 150 is drawn in FIG. 14. FIG. 15 is a schematic plan view of a lower part inside a casing 190 of the heat exchange unit 200. FIG. 16 is a schematic front view of the heat exchange unit 200 with a side plate of the casing 190 removed. FIG. 17 is a schematic right side view of the heat exchange unit 200 with a side plate of the casing 190 removed. FIG. 18 is a schematic rear view of a part of the casing 190 of the heat exchange unit 200 (near a drain pan 80) and the drain pan 80.

Note that, in the following description, expressions indicating directions such as “upper”, “lower”, “left”, “right”, “front (front face)”, and “rear (back face)” may be used. Unless otherwise specified, these directions are indicated by arrows in figures.

First, a difference between the heat load processing system 201 and the heat load processing system 1 of the above-described embodiments will be outlined.

In the heat load processing system 1, the refrigerant is cooled or heated by exchanging heat between air around the heat source unit 300 and the refrigerant, in the heat-source-side heat exchanger 340. Whereas, in the heat load processing system 201, a refrigerant is cooled or heated by heat exchange between the refrigerant and a heat-source-side liquid medium flowing through a heat-source-side liquid medium circuit 500. In one or more embodiments, the heat load processing system 201 is a system in which the refrigerant is cooled by cooling water flowing through the heat-source-side liquid medium circuit 500, and a liquid medium sent to utilization-side equipment 410 is cooled by the refrigerant in the heat exchange unit 200. However, without limiting to this, the heat load processing system 201 may be, for example, a system in which the refrigerant is heated by a heat-source-side liquid medium (for example, waste warm water) flowing through the heat-source-side liquid medium circuit 500, and a liquid medium sent to the utilization-side equipment 410 is heated by the refrigerant in the heat exchange unit 200. In addition, for example, the heat load processing system 201 may be a system capable of execution by switching between: a cooling mode in which the refrigerant is cooled by a relatively low temperature heat-source-side liquid medium flowing through the heat-source-side liquid medium circuit 500, and a liquid medium sent to the utilization-side equipment 410 is cooled by the refrigerant in the heat exchange unit 200; and a heating mode in which the refrigerant is heated by a relatively high temperature heat-source-side liquid medium flowing through the heat-source-side liquid medium circuit 500, and a liquid medium sent to the utilization-side equipment 410 is heated by the refrigerant in the heat exchange unit 200. Note that, in the following, the liquid medium flowing through the heat-source-side liquid medium circuit 500 is referred to as a heat-source-side liquid medium, while the liquid medium sent to the utilization-side equipment 410 is simply referred to as a liquid medium.

Further, in the heat load processing system 1, the refrigerant circuit 50 is formed by the heat source unit 300 and the heat exchange unit 100. Whereas, in the heat load processing system 201, the heat exchange unit 200 has the entire refrigerant circuit 150. In one or more embodiments, one heat exchange unit 200 has three systems of the refrigerant circuit 150. However, the heat exchange unit 200 may have one or two systems of refrigerant circuit 150, or four or more systems of refrigerant circuit 150.

Hereinafter, an overall configuration of the heat load processing system 201 will be described.

The heat load processing system 201 mainly includes the heat exchange unit 200, the heat-source-side liquid medium circuit 500, and the utilization-side equipment 410.

The heat exchange unit 200 is a device that exchanges heat between a liquid medium sent to the utilization-side equipment 410 and a refrigerant, to perform at least one of cooling and heating of the liquid medium. The liquid medium cooled or heated by the liquid refrigerant in the heat exchange unit 200 is sent to the utilization-side equipment 410.

The exemplified heat exchange unit 200 drawn in FIG. 14 is a unit that only cools the liquid medium by exchanging heat between the liquid medium and the refrigerant. However, for example, the configuration is not limited to this, and the heat exchange unit 200 may be a unit that only heats the liquid medium by exchanging heat between the liquid medium and the refrigerant. In addition, similarly to the heat exchange unit 100 of the above-described embodiments, the heat exchange unit 200 may be, for example, a device capable of both cooling and heating of the liquid medium by exchanging heat between the liquid medium and the refrigerant.

Note that the liquid medium and the refrigerant used in one or more embodiments are similar to the liquid medium and the refrigerant described in the above-described embodiments. The description is omitted here. The heat-source-side liquid medium used in one or more embodiments is, for example, water or brine.

The heat-source-side liquid medium circuit 500 is a liquid medium circuit in which the heat-source-side liquid medium that cools the refrigerant in the heat exchange unit 200 circulates. The heat-source-side liquid medium circuit 500 mainly includes heat source equipment 510 and a heat-source-side pump 520.

In one or more embodiments, the heat source equipment 510 is equipment to cool the heat-source-side liquid medium. For example, the heat source equipment 510 is a cooling tower. For example, the cooling tower may be an open type that directly cools the heat-source-side heat medium, or may be a closed type that indirectly cools the heat-source-side heat medium. A type of the heat-source-side liquid medium may be appropriately determined in accordance with a type of the cooling tower and the like. An installation place is not limited, but the heat source equipment 510 is installed, for example, on a rooftop or a space around a building, or the like.

The heat-source-side pump 520 is a pump that sends the heat-source-side liquid medium cooled by the heat source equipment 510, to the heat exchange unit 200. The heat-source-side pump 520 is, for example, a constant speed centrifugal pump. However, the heat-source-side pump 520 is not limited to the centrifugal pump, and a type of the heat-source-side pump 520 may be appropriately selected. Further, the heat-source-side pump 520 may be, for example, a pump having a variable flow rate. Although an installation place is not limited, the heat-source-side pump 520 is installed in a same machine room R as the heat exchange unit 200, for example.

The utilization-side equipment 410 is similar to the utilization-side equipment 410 in the heat load processing system 1 of the above-described embodiments. However, in one or more embodiments, the utilization-side equipment 410 is equipment that uses a liquid medium cooled by the refrigerant. For example, although not limited, the utilization-side equipment 410 is an air handling unit or a fan coil unit used only for cooling. Note that the utilization-side equipment 410 is not limited to the equipment that uses the liquid medium cooled by the refrigerant. When the heat load processing system 201 is configured so that the liquid medium is heated by the refrigerant in the heat exchange unit 200, the utilization-side equipment 410 may be, for example, equipment that uses the liquid medium heated by the refrigerant.

FIG. 14 shows only one piece of utilization-side equipment 410. However, similarly to the above-described embodiments, the heat load processing system 201 may include a plurality of pieces of the utilization-side equipment. In addition, when the heat load processing system 201 includes the plurality of pieces of the utilization-side equipment, types of the pieces of the utilization-side equipment may all be the same, or the pieces of the utilization-side equipment may include a plurality of types of equipment.

(2) Detailed Configuration

The heat exchange unit 200 will be described in detail.

A liquid medium circuit 400A in one or more embodiments is similar to the liquid medium circuit 400 of the above-described embodiments except for the fact that a pump 160 (a device similar to the pump 60 of the above-described embodiments) is arranged outside of the heat exchange unit 200 (a first connection pipe 422), and for a configuration of a liquid medium pipe in the heat exchange unit 200. Here, in the description of the heat exchange unit 200, the liquid medium pipe in the heat exchange unit 200 will be described, and detailed description of other liquid medium circuit 400A will be omitted.

(2-1) Heat Exchange Unit

The heat exchange unit 200 will be described with reference to FIGS. 13 to 18.

The heat exchange unit 200 has three systems of the refrigerant circuit 150. In FIG. 14, only one system of the three systems of the refrigerant circuit 150 is drawn. Since other refrigerant circuits 150 are similar to the refrigerant circuit 150 described here, a description thereof will be omitted here.

Since an installation place of the heat exchange unit 200 is similar to the installation place of the heat exchange unit 100 of the above-described embodiments, a description thereof will be omitted.

The heat exchange unit 200 mainly includes a compressor 130, a heat-source-side heat exchanger 140, an expansion mechanism 120, a utilization-side heat exchanger 110, the casing 190, the drain pan 80, a gas detection sensor 70, and an electric component box 192. The compressor 130, the heat-source-side heat exchanger 140, the expansion mechanism 120, and the utilization-side heat exchanger 110 are connected by a refrigerant pipe 151, to form the refrigerant circuit 150. The refrigerant pipe 151 includes a first refrigerant pipe 151 a that connects a discharge side of the compressor 130 and a gas side of the heat-source-side heat exchanger 140. Further, the refrigerant pipe 151 includes a second refrigerant pipe 151 b that connects a liquid side of the heat-source-side heat exchanger 140 and a liquid side of the utilization-side heat exchanger 110. In the second refrigerant pipe 151 b, the expansion mechanism 120 is arranged. Further, the refrigerant pipe 151 includes a third refrigerant pipe 151 c that connects a gas side of the utilization-side heat exchanger 110 and a suction side of the compressor 130. In the third refrigerant pipe 151 c, an accumulator (not illustrated) may be arranged.

In one or more embodiments, the heat exchange unit 200 is a device that cools the liquid medium with the refrigerant as described above. When the heat exchange unit 200 is a device capable of execution by switching between cooling and heating of the liquid medium with the refrigerant, the refrigerant circuit 150 is provided with a flow path switching mechanism, similarly to the refrigerant circuit 50 of the above-described embodiments.

(2-1-1) Compressor

The compressor 130 suctions a low pressure refrigerant in a refrigeration cycle returning from the utilization-side heat exchanger 110, compresses the refrigerant with a compression mechanism (not illustrated), and sends a high-pressure refrigerant in the refrigeration cycle after compression, to the heat-source-side heat exchanger 140.

The compressor 130 is, for example, a scroll-type compressor. However, a type of the compressor 130 is not limited to the scroll type, and the compressor may be, for example, a screw type, a rotary type, or the like. The compressor 130 is, for example, a compressor having a variable capacity, but may be, for example, a compressor having a constant capacity.

(2-1-2) Heat-Source-Side Heat Exchanger

The heat-source-side heat exchanger 140 is a heat exchanger that exchanges heat between a heat-source-side liquid medium flowing in the heat-source-side heat exchanger 140 and a refrigerant flowing in the heat-source-side heat exchanger 140. Although a type is not limited, the heat-source-side heat exchanger 340 is, for example, a double-tube heat exchanger. However, a type of the heat-source-side heat exchanger 340 is not limited to the double-tube heat exchanger, and it is sufficient to appropriately select a heat exchanger of a type that can be used as a heat exchanger between the refrigerant and the heat-source-side liquid medium.

(2-1-3) Expansion Mechanism

The expansion mechanism 120 is a mechanism that expands a refrigerant flowing through the second refrigerant pipe 151 b, to adjust a pressure and a flow rate of the refrigerant. In one or more embodiments, the expansion mechanism 120 is an electronic expansion valve whose opening degree is adjustable. However, the expansion mechanism 120 is not limited to the electronic expansion valve. For example, the expansion mechanism 120 may be a temperature automatic expansion valve having a temperature sensing cylinder, or may be a capillary tube.

(2-1-4) Utilization-Side Heat Exchanger

The utilization-side heat exchanger 110 exchanges heat between the refrigerant and the liquid medium. In one or more embodiments, the utilization-side heat exchanger 110 is a plate-type heat exchanger. However, a type of the utilization-side heat exchanger 110 is not limited to the plate-type heat exchanger, and it is sufficient to appropriately select a heat exchanger of a type that can be used as a heat exchanger between the refrigerant and the liquid medium.

The utilization-side heat exchanger 110 is connected with the second refrigerant pipe 151 b, the third refrigerant pipe 151 c, a first in-heat-exchange-unit liquid medium pipe 166, and a second in-heat-exchange-unit liquid medium pipe 168. The first in-heat-exchange-unit liquid medium pipe 166 is a pipe that connects a liquid medium inlet 162 of the heat exchange unit 200 and the utilization-side heat exchanger 110. The second in-heat-exchange-unit liquid medium pipe 168 is a pipe that connects the utilization-side heat exchanger 110 and a liquid medium outlet 164 of the heat exchange unit 200. The liquid medium inlet 162 of the heat exchange unit 200 is connected with the first connection pipe 422 that connects the utilization-side equipment 410 and the liquid medium inlet 162 of the heat exchange unit 200. The liquid medium outlet 164 of the heat exchange unit 200 is connected with a second connection pipe 424 that connects the utilization-side equipment 410 and the liquid medium outlet 164 of the heat exchange unit 200.

When the compressor 130 is operated, the refrigerant flows from the second refrigerant pipe 151 b into the utilization-side heat exchanger 110, and flows through a refrigerant flow path (not illustrated) in the utilization-side heat exchanger 110 to flow out to the third refrigerant pipe 151 c. Further, when the pump 160 is operated, the liquid medium having flowed out from the utilization-side equipment 410 flows through the first connection pipe 422 toward the liquid medium inlet 162 of the heat exchange unit 200. The liquid medium having flowed into the heat exchange unit 200 from the liquid medium inlet 162 passes through the first in-heat-exchange-unit liquid medium pipe 166 to flow into the utilization-side heat exchanger 110. When the liquid medium passes through a liquid medium flow path (not illustrated) of the utilization-side heat exchanger 110, the liquid medium is cooled by exchanging heat with the refrigerant flowing through the refrigerant flow path (not illustrated). The liquid medium cooled by the utilization-side heat exchanger 110 flows out to the second in-heat-exchange-unit liquid medium pipe 168, and flows toward the liquid medium outlet 164. The liquid medium having flowed out of the heat exchange unit 200 from the liquid medium outlet 164 flows through the second connection pipe 424 to flow into the utilization-side equipment 410.

(2-1-5) Casing

The casing 190 accommodates various components and various devices of the heat exchange unit 200, including the compressor 130, the heat-source-side heat exchanger 140, the expansion mechanism 120, the utilization-side heat exchanger 110, the drain pan 80, the gas detection sensor 70, and the electric component box 192. A top surface and side surfaces of the heat exchange unit 200 are surrounded by a top panel and side plates (see FIG. 13).

In a lower part of the casing 190 (see FIG. 18), the drain pan 80 is arranged. Above the drain pan 80, the heat-source-side heat exchanger 140 is arranged (see FIG. 18). Further, above the drain pan 80, the utilization-side heat exchanger 110 is arranged (see FIG. 18). The utilization-side heat exchanger 110 is arranged above the heat-source-side heat exchanger 140 (see FIG. 18). The expansion mechanism 120 is arranged above the heat-source-side heat exchanger 140, in a back face side of the casing 190 (see FIG. 18). The electric component box 192 is arranged at an upper front face side of the casing 190 (see FIG. 18). The electric component box 192 is arranged above the heat-source-side heat exchanger 140 (see FIG. 18). The compressor 130 is arranged above the heat-source-side heat exchanger 140.

At least the back face of the casing 190 is provided with an opening 191 b for maintenance (see FIG. 18). The opening 191 b of the casing 190 is closed by a side plate of the casing 190 normally, that is, during operation of the heat load processing system 201. By removing the side plate of the casing 190 provided in the opening 191 b of the casing 190, components and devices inside the casing 190 can be maintained or replaced.

On the back face of the casing 190, there are provided a heat-source-side liquid medium inlet and a heat-source-side liquid medium outlet (not illustrated) to which a pipe of the heat-source-side liquid medium is connected. Further, on the back face of the casing 190, there are provided the liquid medium inlet 162 connected with the first connection pipe 422 and the liquid medium outlet 164 connected with the second connection pipe 424. Although a connection method is not limited, the first connection pipe 422 and the liquid medium inlet 162 are screwed to be connected. Further, although a connection method is not limited, the liquid medium outlet 164 and the second connection pipe 424 are screwed to be connected. Moreover, positions of the heat-source-side liquid medium inlet and the heat-source-side liquid medium outlet, and the liquid medium inlet 162 and the liquid medium outlet 164 are not limited to the positions drawn in the figure, and may be changed as appropriate.

(2-1-6) Drain Pan

The drain pan 80 is arranged in a lower part of the casing 190. In particular, in one or more embodiments, the drain pan 80 is arranged in a lowermost part of the casing 190. The drain pan 80 is arranged below the utilization-side heat exchanger 110. Further, the drain pan 80 is arranged below the heat-source-side heat exchanger 140. The drain pan 80 receives condensation water generated on the utilization-side heat exchanger 110, a pipe through which the liquid medium flows, and the like. When the heat exchange unit 200 is installed outdoors, rainwater or the like also flows into the drain pan 80. The drain pan 80 may have a function as a bottom plate of the casing 190.

The drain pan 80 may be arranged lower than: at least a part of the first in-heat-exchange-unit liquid medium pipe 166 and the second in-heat-exchange-unit liquid medium pipe 168; the refrigerant pipe 151; and the utilization-side heat exchanger 110. In one or more embodiments, the drain pan 80 may be arranged so as to surround most of a lower part of the heat exchange unit 200. For example, in top view, the drain pan 80 covers 80% or more of an area of the heat exchange unit 200 (a bottom area of the casing 190).

A structure of the drain pan 80 of the heat exchange unit 200 of one or more embodiments is similar to that of the drain pan 80 of the heat exchange unit 100 of the above-described embodiments, and thus a description thereof will be omitted here in order to avoid redundancy.

(2-1-7) Gas Detection Sensor

The gas detection sensor 70 is a sensor that detects the presence or absence of refrigerant gas in the internal space Si of the drain pan 80. In one or more embodiments, the gas detection sensor 70 may be a sensor that has the detection element 72, and may detect the presence or absence of refrigerant gas at a place where the detection element 72 is arranged. The gas detection sensor 70 is a sensor similar to the gas detection sensor 70 of the above-described embodiments.

Similarly to the above-described embodiments, the detection element 72 of the gas detection sensor 70 is arranged in the internal space Si of the drain pan 80 located at the lower part in the casing 190. Further, similarly to the above-described embodiments, the detection element 72 may be arranged on a lower end 82 ab side of an inclined part 82 a of a bottom plate 82 of the drain pan 80 (in one or more embodiments, a rear end side of the bottom plate 82). Further, similarly to the above-described embodiments, the detection element 72 may be arranged near a drain port 86 a, which is a discharge port for water from the internal space Si of the drain pan 80. By arranging the detection element 72 at such a position where refrigerant gas is likely to accumulate, highly reliable refrigerant leakage detection is possible.

However, the position where the detection element 72 of the gas detection sensor 70 is arranged is not limited to a specific position in the internal space Si of the drain pan 80, similarly to the above-described embodiments. Alternatively, the position where the detection element 72 of the gas detection sensor 70 is arranged may be, similarly to the above-described embodiments, a place outside the internal space Si of the drain pan 80 and where the gas in the internal space Si of the drain pan 80 can be detected.

Further, similarly to the above-described embodiments, the detection element 72 of the gas detection sensor 70 may be arranged below the electric component that can be an ignition source.

Note that the electric component that can be an ignition source include an electric component that may generate an electric spark. In one or more embodiments, the electric components that can be an ignition source include: the electric component 93 such as an electromagnetic switch, a contactor, and a relay, and the inverter board 194 for the compressor 130, which are accommodated in the electric component box 192; an electronic expansion valve as an example of the expansion mechanism 120; and the terminal box 131 of the compressor 130. The terminal box 131 of the compressor 130 is connected with an electric wire (not illustrated) for supply of electric power to a motor 130 a of the compressor 130.

Further, although it is not mounted on the heat exchange unit 200 in one or more embodiments, a heater may be arranged in the heat exchange unit 200 when the heat exchange unit 200 is installed in a cold region. Depending on specifications, the heater can be hot enough to be an ignition source. In one or more embodiments, the electric component that can become hot enough to be an ignition source may also be arranged above the detection element 72 of the gas detection sensor 70.

Moreover, in one or more embodiments, the electric component that can be an ignition source (in one or more embodiments: the electric components 93 such as an electromagnetic switch, a contactor, and a relay, and the inverter board 194 for the compressor 130, which are accommodated in the electric component box 192; an electronic expansion valve as an example of the expansion mechanism 120; and the terminal box 131 of the compressor 130) may be arranged at a high position of 300 mm or more from the bottom of the casing 190 (see FIGS. 16 and 17). By arranging the electric component that can be an ignition source at such a height position, the possibility of ignition with the electric component in the casing 190 as the ignition source is reduced even if the refrigerant leaks.

Further, from the viewpoint of maintenance, the detection element 72 of the gas detection sensor 70 may be arranged in a space near (e.g., adjacent to) the opening 191 b for maintenance, in the casing 190. The space near the opening 191 b is a space accessible to a worker from the opening 191 b. For example, the space near the opening 191 b may be a space within hand reach from the opening 191 b (for example, a space within 50 cm from the opening 191 b). An arrangement of the detection element 72 of the gas detection sensor 70 at such a position allows the detection element 72 to be easily replaced and inspected by removing the side plate of the casing 190 that closes the opening 191 b.

Further, since the detection element 72 of the gas detection sensor 70 detects the refrigerant gas, the gas detection sensor 70 may have a structure in which the detection element 72 is less likely to be immersed even if condensation water accumulates in the internal space Si of the drain pan 80. For example, similarly to the above-described embodiments, the heat exchange unit 200 may have a float 88 arranged in the internal space Si of the drain pan 80, and the detection element 72 of the gas detection sensor 70 may be attached to an upper surface 88 a of the float 88 or a side surface 88 b of the float 88. Here, in order to avoid redundancy of description, the description of the float 88 will be omitted.

Further, the detection element 72 of the gas detection sensor 70 may be directly attached to the side wall 84 of the drain pan 80 or a frame (not illustrated) of the casing 90. In this case, the detection element 72 of the gas detection sensor 70 may be arranged at a position that is less likely to be immersed, for example, a position higher than the drain port 86 a in the internal space Si of the drain pan 80, as shown by reference numeral 72 a in FIG. 18.

Meanwhile, for a position of the detection element 72 of the gas detection sensor 70, a position of the electric component that can be an ignition source, and a positional relationship between the detection element 72 of the gas detection sensor 70 and the electric component that can be an ignition source, the matters described in (2-4-6) of the above-described embodiments may be applied, as long as there is no contradiction.

(2-1-8) Electric Component Box

The electric component box 192 is a case that accommodates various electric components. The electric component box 192 accommodates the heat-exchange-unit side control board 195, a power source terminal block (not illustrated), the inverter board 194 for the compressor 130, and the electric components 93 such as an electromagnetic switch, a contactor, and a relay (see FIG. 14). The electric component 93 need not include all of the electromagnetic switch, the contactor, and the relay, but may include any of the electromagnetic switch, the contactor, and the relay. Note that the electric components accommodated in the electric component box 192 are not limited to those exemplified, and various electric components are accommodated as needed.

The heat-exchange-unit side control board 195 has various electric circuits, a microcomputer including a CPU and a memory that stores a program executed by the CPU, and the like.

The heat-exchange-unit side control board 195 controls an operation of each part of the heat exchange unit 200.

The heat-exchange-unit side control board 195 is electrically connected to various devices of the heat exchange unit 200. The various devices of the heat exchange unit 200 connected to the heat-exchange-unit side control board 195 include the compressor 130 and the expansion mechanism 120. Further, in one or more embodiments, the heat-exchange-unit side control board 195 may transmit a control signal to the pump 160, the heat-source-side pump 520, and the like. Further, the heat-exchange-unit side control board 195 is communicably connected to various sensors provided to the heat exchange unit 200, and receives measured values from the various sensors (not illustrated). The various sensors provided to the heat exchange unit 200 include, but not limited to, for example, a temperature sensor that is provided in the first refrigerant pipe 151 a and the third refrigerant pipe 151 c and measures a temperature of a refrigerant, a pressure sensor that is provided in the first refrigerant pipe 151 a and measures a pressure of the refrigerant, a temperature sensor that is provided in the first in-heat-exchange-unit liquid medium pipe 166 and the second in-heat-exchange-unit liquid medium pipe 168 and measures the temperature of the liquid medium, and the like. Further, the heat-exchange-unit side control board 195 is communicably connected to the gas detection sensor 70 of the heat exchange unit 200.

The heat-exchange-unit side control board 195 controls an operation of various devices of the heat exchange unit 200 and an operation of the pump 160 and the heat-source-side pump 520, in response to an operation or stop command given from an operation device (not illustrated). Further, the heat-exchange-unit side control board 195 controls an operation of various devices of the heat exchange unit 200 such that the liquid refrigerant is cooled to reach a predetermined target temperature and flows out from the liquid medium outlet 164 of the heat exchange unit 200. Note that an operating principle of a vapor compression refrigerator is generally well known, and thus a description thereof is omitted here. Further, when the gas detection sensor 70 detects leakage of refrigerant gas, the heat-exchange-unit side control board 195 controls devices such that the various devices of the heat exchange unit 200, the pump 160, and the heat-source-side pump 520 perform a predetermined operation at a time of leakage.

(3) Characteristics

(3-1)

The heat exchange unit 200 of the above-described embodiments exchanges heat between the liquid medium sent to the utilization-side equipment 410 and the refrigerant, to perform at least one of cooling and heating of the liquid medium. The heat exchange unit 200 includes the utilization-side heat exchanger 110 as an example of a heat exchanger, the casing 190, the drain pan 80, and the gas detection sensor 70 as an example of a first gas detection sensor. The utilization-side heat exchanger 110 exchanges heat between the flammable refrigerant and the liquid medium. The casing 190 accommodates the utilization-side heat exchanger 110. The drain pan 80 is arranged below the utilization-side heat exchanger 110, in a lower part of the casing 190. The drain pan 80 has the bottom plate 82 and the side wall 84 extending upward from the bottom plate 82. The gas detection sensor 70 detects the presence or absence of refrigerant gas in the internal space Si of the drain pan 80, the internal space Si being located above the bottom plate 82 of the drain pan 80 and below the upper end part of the side wall 84 of the drain pan 80.

The refrigerant gas is usually heavier than air. Therefore, when the refrigerant leaks, the leaked refrigerant gas moves downward. Therefore, in this heat exchange unit 200, leaked refrigerant gas tends to accumulate in the drain pan 80 that is arranged in the lower part of the casing 190 and receives dew condensation water generated on the pipe, the heat exchanger, and the like.

Here, highly reliable leakage detection of refrigerant gas is possible by detecting the presence or absence of refrigerant gas in the internal space Si of the drain pan 80 where leaked refrigerant gas tends to accumulate.

In one or more embodiments, the gas detection sensor 70 may have, as an example of a first detection element, the detection element 72 that is arranged in the internal space Si of the drain pan 80, and detects the presence or absence of the refrigerant gas at a place where the detection element 72 is arranged.

Here, by arranging the detection element 72 of the gas detection sensor 70 in the internal space Si of the drain pan 80 where leaked refrigerant gas tends to accumulate, highly reliable refrigerant leakage detection is possible.

(3-2)

In the heat exchange unit 200 of the above-described embodiments, the bottom plate 82 of the drain pan 80 has the inclined part 82 a that is inclined with respect to a horizontal plane. The detection element 72 is arranged on a lower end side of the inclined part 82 a.

Here, since the detection element of the gas detection sensor 70 is arranged on the lower end side of the inclined part 82 a where the refrigerant gas tends to accumulate, highly reliable refrigerant leakage detection is possible.

(3-3)

In the heat exchange unit 200 of the above-described embodiments, at least one of the bottom plate 82 or the side wall 84 of the drain pan 80 is provided with the drain port 86 a for discharge of water in the internal space Si of the drain pan 80. The detection element 72 is provided near (e.g., adjacent to) the drain port 86 a.

Here, since the detection element 72 of the gas detection sensor 70 is arranged near the drain port 86 a of the drain pan 80 that is arranged at a position where water is easily discharged, highly reliable refrigerant leakage detection is possible.

(3-4)

The heat exchange unit 200 of the above-described embodiments includes the float 88 arranged in the internal space Si of the drain pan 80. The detection element 72 is attached to the upper surface 88 a or the side surface 88 b of the float 88.

Here, since the detection element 72 of the gas detection sensor 70 is attached to the upper surface 88 a or the side surface 88 b of the float 88, it is possible to detect refrigerant leakage even when water accumulates in the drain pan 80.

(3-5)

In the heat exchange unit 200 of the above-described embodiments, the casing 190 is formed with the opening 191 b for maintenance. The detection element 72 is arranged in a space near (e.g., adjacent to) the opening 191 b.

Here, since the detection element 72 of the gas detection sensor 70 is arranged in the space near the opening 191 b for maintenance, the detection element 72 of the gas detection sensor 70 can be easily inspected or replaced.

(4) Modified Examples (4-1) Modified Example 2A

The heat exchange unit 200 of the above-described embodiments does not have a pump 160 or a heat-source-side pump 520, but the configuration is not limited thereto. The heat exchange unit 200 may have the pump 160 and/or the heat-source-side pump 520 arranged inside the casing 190.

(4-2) Modified Example 2B

Similarly to Modified example 1B of the above-described embodiments, the heat exchange unit 200 may further have an auxiliary gas detection sensor having a detection element arranged outside the casing 90, in addition to the gas detection sensor 70 having the detection element arranged in the internal space Si of the drain pan 80. Detailed description will be omitted.

(4-3) Modified Example 2C

In the above-described embodiments, a liquid medium cooled or heated by the heat exchange unit 200 circulates in the liquid medium circuit 400, but the configuration is not limited to this. For example, when the cooled or heated liquid medium itself is used directly, the liquid medium sent to the utilization-side equipment 410 (for example, a tank) may be used as it is without circulating in the liquid medium circuit 400.

Further, similarly, the heat-source-side liquid medium that exchanges heat with the refrigerant circulates in the heat-source-side liquid medium circuit 500, but the configuration is not limited to this. For example, the heat-source-side liquid medium may be groundwater or warm wastewater. Then, the heat load processing system 201 may not include the heat source equipment 510, and the heat-source-side liquid medium that has exchanged heat with the refrigerant in the heat-source-side heat exchanger 140 may be drained as it is.

Although the disclosure has been described with respect to only a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that various other embodiments may be devised without departing from the scope of the above-described embodiments. Accordingly, the scope of the above-described embodiments should be limited only by the attached claims.

INDUSTRIAL APPLICABILITY

It is widely applicable and useful for heat exchange units that use flammable refrigerants.

REFERENCE SIGNS LIST

-   -   10, 110: utilization-side heat exchanger (heat exchanger)     -   60: pump     -   70: gas detection sensor (first gas detection sensor)     -   72: detection element (first detection element)     -   80: drain pan     -   82: bottom plate     -   82 a: inclined part     -   82 ab: lower end of inclined part     -   84: side wall     -   86 a: drain port     -   88: float     -   88 a: upper surface of float     -   88 b: side surface of float     -   90, 190: casing     -   91 b, 191 b: opening of casing     -   100, 200: heat exchange unit     -   270: additional gas detection sensor (second gas detection         sensor)     -   272: detection element (second detection element)     -   410: utilization-side equipment     -   A1: pump arrangement area     -   A2: refrigerant side area     -   Si: internal space 

1.-8. (canceled)
 9. A heat exchange unit that performs at least one of a cooling and a heating of a liquid medium that is sent to a utilization side equipment, the heat exchange unit comprising: a heat exchanger that exchanges heat between a flammable refrigerant and the liquid medium; a casing that accommodates the heat exchanger; a drain pan with a bottom plate and a side wall that extends upward from the bottom plate, wherein the drain pan is disposed below the heat exchanger in a lower part of the casing; and a first gas detection sensor that detects presence or absence of a gas of the refrigerant in an internal space of the drain pan, wherein the internal space is a space within the drain pan that is surrounded by the bottom plate, the side wall, and a virtual plane passing through an upper end part of the side wall.
 10. The heat exchange unit according to claim 9, wherein the first gas detection sensor has a first detection element disposed in the internal space of the drain pan, and the first gas detection sensor detects the presence or the absence of the gas of the refrigerant at a place where the first detection element is disposed.
 11. The heat exchange unit according to claim 10, wherein the bottom plate of the drain pan has an inclined part that is inclined with respect to a horizontal plane, and the first detection element is arranged on a lower end side of the inclined part.
 12. The heat exchange unit according to claim 10, wherein at least one of the bottom plate and the side wall of the drain pan includes a drain port that discharges water from the internal space of the drain pan, and the first detection element is disposed adjacent to the drain port.
 13. The heat exchange unit according to claim 10, further comprising a float disposed in the internal space of the drain pan, wherein the first detection element is attached to an upper surface or a side surface of the float.
 14. The heat exchange unit according to claim 10, further comprising a second gas detection sensor with a second detection element disposed outside the casing, wherein the second gas detection sensor detects the presence or the absence of the gas of the refrigerant at a place where the second detection element is disposed.
 15. The heat exchange unit according to claim 10, wherein an opening is formed in the casing, and the first detection element is disposed in a space adjacent to the opening.
 16. The heat exchange unit according to claim 10, further comprising a pump that is disposed inside the casing and that sends the liquid medium to the utilization-side equipment, wherein in plan view, an inside of the casing is sectioned into at least: a pump arrangement area where the pump is disposed; and a refrigerant side area where a refrigerant pipe through which the refrigerant flows or the heat exchanger is disposed, and the first detection element is disposed closer to the refrigerant side area than the pump arrangement area in plan view. 